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coral / linux-imx / refs/tags/9-3 / . / drivers / mxc / sim / imx_sim.c
blob: e907bd3a8ec83a78592be722733547b8fb8000fb [file] [log] [blame]
/*
* Copyright (C) 2015 Freescale Semiconductor, Inc. All Rights Reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <linux/module.h>
#include <linux/ioport.h>
#include <linux/kernel.h>
#include <linux/delay.h>
#include <linux/sched.h>
#include <linux/io.h>
#include <linux/interrupt.h>
#include <linux/of.h>
#include <linux/of_device.h>
#include <linux/poll.h>
#include <linux/miscdevice.h>
#include <linux/clk.h>
#include <linux/types.h>
#include <linux/platform_device.h>
#include <linux/mxc_sim_interface.h>
#include <linux/spinlock.h>
#include <linux/time.h>
#include <linux/io.h>
#define DRIVER_NAME "mxc_sim"
#define SIM_INTERNAL_CLK (0)
#define SIM_RFU (-1)
/* Transmit and receive buffer sizes */
#define SIM_XMT_BUFFER_SIZE (300)
#define SIM_RCV_BUFFER_SIZE (400)
#define SIM_TX_FIFO_DEPTH (16)
#define SIM_RX_FIFO_DEPTH (285)
#define TX_FIFO_THRESHOLD (0x04)
#define RX_FIFO_THRESHOLD (250)
/* Interface character references */
#define SIM_IFC_TXI(letter, number) (letter + number * 4)
#define SIM_IFC_TA1 SIM_IFC_TXI(0, 0)
#define SIM_IFC_TB1 SIM_IFC_TXI(0, 1)
#define SIM_IFC_TC1 SIM_IFC_TXI(0, 2)
#define SIM_IFC_TD1 SIM_IFC_TXI(0, 3)
#define SIM_IFC_TA2 SIM_IFC_TXI(1, 0)
#define SIM_IFC_TB2 SIM_IFC_TXI(1, 1)
#define SIM_IFC_TC2 SIM_IFC_TXI(1, 2)
#define SIM_IFC_TD2 SIM_IFC_TXI(1, 3)
#define SIM_IFC_TA3 SIM_IFC_TXI(2, 0)
#define SIM_IFC_TB3 SIM_IFC_TXI(2, 1)
#define SIM_IFC_TC3 SIM_IFC_TXI(2, 2)
#define SIM_IFC_TD3 SIM_IFC_TXI(2, 3)
#define SIM_IFC_TA4 SIM_IFC_TXI(3, 0)
#define SIM_IFC_TB4 SIM_IFC_TXI(3, 1)
#define SIM_IFC_TC4 SIM_IFC_TXI(3, 2)
#define SIM_IFC_TD4 SIM_IFC_TXI(3, 3)
/* ATR and OPS states */
#define SIM_STATE_REMOVED (0)
#define SIM_STATE_DETECTED (1)
#define SIM_STATE_ATR_RECEIVING (2)
#define SIM_STATE_ATR_RECEIVED (3)
#define SIM_STATE_XMTING (4)
#define SIM_STATE_XMT_DONE (5)
#define SIM_STATE_XMT_ERROR (6)
#define SIM_STATE_RECEIVING (7)
#define SIM_STATE_RECEIVE_DONE (8)
#define SIM_STATE_RECEIVE_ERROR (9)
#define SIM_STATE_RESET_SEQUENCY (10)
/* Definitions of the offset of the SIM hardware registers */
#define PORT1_CNTL (0x00)
#define SETUP (0x04)
#define PORT1_DETECT (0x08)
#define PORT1_XMT_BUF (0x0C)
#define PORT1_RCV_BUF (0x10)
#define PORT0_CNTL (0x14)
#define CNTL (0x18)
#define CLK_PRESCALER (0x1C)
#define RCV_THRESHOLD (0x20)
#define ENABLE (0x24)
#define XMT_STATUS (0x28)
#define RCV_STATUS (0x2C)
#define INT_MASK (0x30)
#define PORTO_XMT_BUF (0x34)
#define PORT0_RCV_BUF (0x38)
#define PORT0_DETECT (0x3C)
#define DATA_FORMAT (0x40)
#define XMT_THRESHOLD (0x44)
#define GUARD_CNTL (0x48)
#define OD_CONFIG (0x4C)
#define RESET_CNTL (0x50)
#define CHAR_WAIT (0x54)
#define GPCNT (0x58)
#define DIVISOR (0x5C)
#define BWT (0x60)
#define BGT (0x64)
#define BWT_H (0x68)
#define XMT_FIFO_STAT (0x6C)
#define RCV_FIFO_CNT (0x70)
#define RCV_FIFO_WPTR (0x74)
#define RCV_FIFO_RPTR (0x78)
/* SIM SETUP register bits */
#define SIM_SETUP_SPS_PORT0 (0 << 1)
#define SIM_SETUP_SPS_PORT1 (1 << 1)
/* SIM port[0|1]_cntl register bits */
#define SIM_PORT_CNTL_SFPD (1 << 7)
#define SIM_PORT_CNTL_3VOLT (1 << 6)
#define SIM_PORT_CNTL_SCSP (1 << 5)
#define SIM_PORT_CNTL_SCEN (1 << 4)
#define SIM_PORT_CNTL_SRST (1 << 3)
#define SIM_PORT_CNTL_STEN (1 << 2)
#define SIM_PORT_CNTL_SVEN (1 << 1)
#define SIM_PORT_CNTL_SAPD (1 << 0)
/* SIM od_config register bits */
#define SIM_OD_CONFIG_OD_P1 (1 << 1)
#define SIM_OD_CONFIG_OD_P0 (1 << 0)
/* SIM enable register bits */
#define SIM_ENABLE_XMTEN (1 << 1)
#define SIM_ENABLE_RCVEN (1 << 0)
#define SIM_ESTOP_EN (1 << 5)
#define SIM_ESTOP_EXE (1 << 6)
/* SIM int_mask register bits */
#define SIM_INT_MASK_RFEM (1 << 13)
#define SIM_INT_MASK_BGTM (1 << 12)
#define SIM_INT_MASK_BWTM (1 << 11)
#define SIM_INT_MASK_RTM (1 << 10)
#define SIM_INT_MASK_CWTM (1 << 9)
#define SIM_INT_MASK_GPCM (1 << 8)
#define SIM_INT_MASK_TDTFM (1 << 7)
#define SIM_INT_MASK_TFOM (1 << 6)
#define SIM_INT_MASK_XTM (1 << 5)
#define SIM_INT_MASK_TFEIM (1 << 4)
#define SIM_INT_MASK_ETCIM (1 << 3)
#define SIM_INT_MASK_OIM (1 << 2)
#define SIM_INT_MASK_TCIM (1 << 1)
#define SIM_INT_MASK_RIM (1 << 0)
/* SIM xmt_status register bits */
#define SIM_XMT_STATUS_GPCNT (1 << 8)
#define SIM_XMT_STATUS_TDTF (1 << 7)
#define SIM_XMT_STATUS_TFO (1 << 6)
#define SIM_XMT_STATUS_TC (1 << 5)
#define SIM_XMT_STATUS_ETC (1 << 4)
#define SIM_XMT_STATUS_TFE (1 << 3)
#define SIM_XMT_STATUS_XTE (1 << 0)
/* SIM rcv_status register bits */
#define SIM_RCV_STATUS_BGT (1 << 11)
#define SIM_RCV_STATUS_BWT (1 << 10)
#define SIM_RCV_STATUS_RTE (1 << 9)
#define SIM_RCV_STATUS_CWT (1 << 8)
#define SIM_RCV_STATUS_CRCOK (1 << 7)
#define SIM_RCV_STATUS_LRCOK (1 << 6)
#define SIM_RCV_STATUS_RDRF (1 << 5)
#define SIM_RCV_STATUS_RFD (1 << 4)
#define SIM_RCV_STATUS_RFE (1 << 1)
#define SIM_RCV_STATUS_OEF (1 << 0)
/* SIM cntl register bits */
#define SIM_CNTL_BWTEN (1 << 15)
#define SIM_CNTL_XMT_CRC_LRC (1 << 14)
#define SIM_CNTL_CRCEN (1 << 13)
#define SIM_CNTL_LRCEN (1 << 12)
#define SIM_CNTL_CWTEN (1 << 11)
#define SIM_CNTL_SAMPLE12 (1 << 4)
#define SIM_CNTL_ONACK (1 << 3)
#define SIM_CNTL_ANACK (1 << 2)
#define SIM_CNTL_ICM (1 << 1)
#define SIM_CNTL_GPCNT_CLK_SEL(x) ((x&0x03) << 9)
#define SIM_CNTL_GPCNT_CLK_SEL_MASK (0x03 << 9)
#define SIM_CNTL_BAUD_SEL(x) ((x&0x07) << 6)
#define SIM_CNTL_BAUD_SEL_MASK (0x07 << 6)
#define SIM_CNTL_GPCNT_CARD_CLK 1
#define SIM_CNTL_GPCNT_RCV_CLK 2
#define SIM_CNTL_GPCNT_ETU_CLK 3
/* SIM rcv_threshold register bits */
#define SIM_RCV_THRESHOLD_RTH(x) ((x&0x0f) << 9)
#define SIM_RCV_THRESHOLD_RTH_MASK (0x0f << 9)
#define SIM_RCV_THRESHOLD_RDT(x) ((x&0x1ff) << 0)
#define SIM_RCV_THRESHOLD_RDT_MASK (0x1ff << 0)
/* SIM xmt_threshold register bits */
#define SIM_XMT_THRESHOLD_XTH(x) ((x&0x0f) << 4)
#define SIM_XMT_THRESHOLD_XTH_MASK (0x0f << 4)
#define SIM_XMT_THRESHOLD_TDT(x) ((x&0x0f) << 0)
#define SIM_XMT_THRESHOLD_TDT_MASK (0x0f << 0)
/* SIM guard_cntl register bits */
#define SIM_GUARD_CNTL_RCVR11 (1 << 8)
#define SIM_GIARD_CNTL_GETU(x) (x&0xff)
#define SIM_GIARD_CNTL_GETU_MASK (0xff)
/* SIM port[0|]_detect register bits */
#define SIM_PORT_DETECT_SPDS (1 << 3)
#define SIM_PORT_DETECT_SPDP (1 << 2)
#define SIM_PORT_DETECT_SDI (1 << 1)
#define SIM_PORT_DETECT_SDIM (1 << 0)
/* SIM RESET_CNTL register bits*/
#define SIM_RESET_CNTL_FLUSH_RCV (1 << 0)
#define SIM_RESET_CNTL_FLUSH_XMT (1 << 1)
#define SIM_RESET_CNTL_SOFT_RESET (1 << 2)
#define SIM_RESET_CNTL_KILL_CLOCK (1 << 3)
#define SIM_RESET_CNTL_DOZE (1 << 4)
#define SIM_RESET_CNTL_STOP (1 << 5)
#define SIM_RESET_CNTL_DEBUG (1 << 6)
/*SIM receive buffer register error status*/
#define SIM_REC_CWT_ERROR (1 << 10)
#define SIM_REC_FRAME_ERROR (1 << 9)
#define SIM_REC_PARITY_ERROR (1 << 8)
#define SIM_EMV_NACK_THRESHOLD (5)
#define EMV_T0_BGT (16)
#define EMV_T1_BGT (22)
#define ATR_THRESHOLD_MAX (100)
#define ATR_MAX_CWT (10080)
#define ATR_MAX_DURATION (20160)
#define FCLK_FREQ (4000000)
#define ATR_TIMEOUT (5)
#define TX_TIMEOUT (10)
#define RX_TIMEOUT (100)
#define RESET_RETRY_TIMES (5)
#define SIM_QUIRK_TKT259347 (1 << 0)
#define EMV_RESET_LOW_CYCLES 40000
#define ATR_MAX_DELAY_CLK 46400
/* Main SIM driver structure */
struct sim_t{
s32 present;
u8 open_cnt;
int state;
struct clk *clk;
struct resource *res;
void __iomem *ioaddr;
int ipb_irq;
int dat_irq;
/* error code occured during transfer */
int errval;
int protocol_type;
sim_timing_t timing_data;
sim_baud_t baud_rate;
int timeout;
u8 nack_threshold;
u8 nack_enable;
u32 expected_rcv_cnt;
u8 is_fixed_len_rec;
/* remaining bytes to transmit for the current transfer */
u32 xmt_remaining;
/* transmit position */
u32 xmt_pos;
/* receive position / number of bytes received */
u32 rcv_count;
u8 rcv_buffer[SIM_RCV_BUFFER_SIZE];
u8 xmt_buffer[SIM_XMT_BUFFER_SIZE];
/* transfer completion notifier */
struct completion xfer_done;
/* async notifier for card and ATR detection */
struct fasync_struct *fasync;
/* Platform specific data */
struct mxc_sim_platform_data *plat_data;
bool last_is_tx;
u16 rcv_head;
spinlock_t lock;
bool sven_low_active;
u32 port_index;
u32 port_detect_reg;
u32 port_ctrl_reg;
u32 clk_rate;
u32 quirks;
u8 checking_ts_timing;
};
static struct miscdevice sim_dev;
static void sim_data_reset(struct sim_t *sim)
{
sim->errval = SIM_OK;
sim->protocol_type = 0;
sim->timeout = 0;
sim->nack_threshold = SIM_EMV_NACK_THRESHOLD;
sim->nack_enable = 0;
memset(&sim->timing_data, 0, sizeof(sim->timing_data));
memset(&sim->baud_rate, 0, sizeof(sim->baud_rate));
sim->xmt_remaining = 0;
sim->xmt_pos = 0;
sim->rcv_count = 0;
sim->rcv_head = 0;
sim->last_is_tx = false;
memset(sim->rcv_buffer, 0, SIM_RCV_BUFFER_SIZE);
memset(sim->xmt_buffer, 0, SIM_XMT_BUFFER_SIZE);
init_completion(&sim->xfer_done);
};
static void sim_set_nack(struct sim_t *sim, u8 enable)
{
u32 reg_val;
reg_val = __raw_readl(sim->ioaddr + CNTL);
/*Disable overrun NACK setting for now*/
reg_val &= ~(SIM_CNTL_ONACK);
if (enable) {
reg_val |= SIM_CNTL_ANACK;
__raw_writel(reg_val, sim->ioaddr + CNTL);
reg_val = __raw_readl(sim->ioaddr + XMT_THRESHOLD);
reg_val &= ~(SIM_XMT_THRESHOLD_XTH_MASK);
reg_val |= SIM_XMT_THRESHOLD_XTH(sim->nack_threshold);
__raw_writel(reg_val, sim->ioaddr + XMT_THRESHOLD);
} else {
reg_val &= ~SIM_CNTL_ANACK;
__raw_writel(reg_val, sim->ioaddr + CNTL);
}
sim->nack_enable = enable;
}
static void sim_set_tx(struct sim_t *sim, u8 enable)
{
u32 reg_data;
reg_data = __raw_readl(sim->ioaddr + ENABLE);
if (enable) {
reg_data |= SIM_ENABLE_XMTEN | SIM_ENABLE_RCVEN;
if (sim->quirks & SIM_QUIRK_TKT259347)
reg_data &= ~(SIM_ESTOP_EN | SIM_ESTOP_EXE);
} else
reg_data &= ~SIM_ENABLE_XMTEN;
__raw_writel(reg_data, sim->ioaddr + ENABLE);
}
static void sim_set_rx(struct sim_t *sim, u8 enable)
{
u32 reg_data;
reg_data = __raw_readl(sim->ioaddr + ENABLE);
if (enable) {
reg_data |= SIM_ENABLE_RCVEN;
reg_data &= ~SIM_ENABLE_XMTEN;
if (sim->quirks & SIM_QUIRK_TKT259347)
reg_data |= (SIM_ESTOP_EN | SIM_ESTOP_EXE);
} else {
reg_data &= ~SIM_ENABLE_RCVEN;
if (sim->quirks & SIM_QUIRK_TKT259347)
reg_data &= ~(SIM_ESTOP_EN | SIM_ESTOP_EXE);
}
__raw_writel(reg_data, sim->ioaddr + ENABLE);
}
static void sim_reset_timer(struct sim_t *sim)
{
u32 reg_data;
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~SIM_CNTL_GPCNT_CLK_SEL_MASK;
__raw_writel(reg_data, sim->ioaddr + CNTL);
}
static void sim_start_timer(struct sim_t *sim, u8 clk_source)
{
u32 reg_data;
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~SIM_CNTL_GPCNT_CLK_SEL_MASK;
reg_data |= SIM_CNTL_GPCNT_CLK_SEL(clk_source);
writel(reg_data, sim->ioaddr + CNTL);
}
static void sim_set_gpc_timer(struct sim_t *sim, u32 val)
{
uint32_t reg_data;
/*Clear the interrupt status*/
reg_data = __raw_readl(sim->ioaddr + XMT_STATUS);
reg_data |= SIM_XMT_STATUS_GPCNT;
__raw_writel(reg_data, sim->ioaddr + XMT_STATUS);
/*Set the timer counter*/
__raw_writel(val, sim->ioaddr + GPCNT);
/*First reset the counter*/
sim_reset_timer(sim);
/*Enable GPC timer interrupt*/
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data &= ~SIM_INT_MASK_GPCM;
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
/*Set the GPCNT clock source to be Fclk*/
sim_start_timer(sim, SIM_CNTL_GPCNT_CARD_CLK);
}
static int sim_reset_low_timing(struct sim_t *sim, u32 clock_cycle)
{
int errval = 0;
int timeout = 0;
u32 fclk_in_khz, delay_in_us, reg_data;
fclk_in_khz = sim->clk_rate / MSEC_PER_SEC;
delay_in_us = EMV_RESET_LOW_CYCLES * USEC_PER_MSEC / fclk_in_khz;
sim_set_gpc_timer(sim, clock_cycle);
timeout = wait_for_completion_timeout(&sim->xfer_done,
msecs_to_jiffies(delay_in_us / 1000 * 2));
if (timeout == 0) {
pr_err("Reset low GPC timout\n");
errval = -SIM_E_TIMEOUT;
}
sim_reset_timer(sim);
/*Disable GPC timer interrupt*/
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= SIM_INT_MASK_GPCM;
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
return errval;
}
static void sim_set_cwt(struct sim_t *sim, u8 enable)
{
u32 reg_val;
reg_val = __raw_readl(sim->ioaddr + CNTL);
if (enable && sim->timing_data.cwt)
reg_val |= SIM_CNTL_CWTEN;
else
reg_val &= ~SIM_CNTL_CWTEN;
__raw_writel(reg_val, sim->ioaddr + CNTL);
}
static void sim_set_bwt(struct sim_t *sim, u8 enable)
{
u32 reg_val;
reg_val = __raw_readl(sim->ioaddr + CNTL);
if (enable && (sim->timing_data.bwt || sim->timing_data.bgt))
reg_val |= SIM_CNTL_BWTEN;
else
reg_val &= ~SIM_CNTL_BWTEN;
__raw_writel(reg_val, sim->ioaddr + CNTL);
}
static int sim_reset_module(struct sim_t *sim)
{
u32 reg_val;
s8 timeout = RESET_RETRY_TIMES;
reg_val = __raw_readl(sim->ioaddr + RESET_CNTL);
reg_val |= (SIM_RESET_CNTL_SOFT_RESET);
__raw_writel(reg_val, sim->ioaddr + RESET_CNTL);
while (__raw_readl(sim->ioaddr + RESET_CNTL) & SIM_RESET_CNTL_SOFT_RESET) {
usleep_range(1, 3);
if (timeout-- <= 0) {
pr_err("SIM module reset timeout\n");
return -EINVAL;
}
}
return 0;
}
static void sim_receive_atr_set(struct sim_t *sim)
{
u32 reg_data;
/*Enable RX*/
sim_set_rx(sim, 1);
/*Receive fifo threshold = 1*/
reg_data = SIM_RCV_THRESHOLD_RTH(0) | SIM_RCV_THRESHOLD_RDT(1);
__raw_writel(reg_data, sim->ioaddr + RCV_THRESHOLD);
/* Clear the interrupt status*/
reg_data = __raw_readl(sim->ioaddr + RCV_STATUS);
reg_data |= (SIM_RCV_STATUS_CWT | SIM_RCV_STATUS_RDRF);
__raw_writel(reg_data, sim->ioaddr + RCV_STATUS);
/*Set the cwt timer.Refer the setting of ATR on EMV4.3 book*/
__raw_writel(ATR_MAX_CWT, sim->ioaddr + CHAR_WAIT);
/*Set the baud rate to be 1/372. Refer the setting of ATR on EMV4.3 book
*Enable the CWT timer during receiving ATR process.
*/
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~SIM_CNTL_BAUD_SEL_MASK;
reg_data |= SIM_CNTL_BAUD_SEL(0) | SIM_CNTL_CWTEN;
/*Enable ICM mode*/
reg_data |= SIM_CNTL_ICM;
/*Enable Sample12*/
reg_data |= SIM_CNTL_SAMPLE12;
__raw_writel(reg_data, sim->ioaddr + CNTL);
/*Disable NACK*/
sim_set_nack(sim, 0);
/*Set 12 ETUS*/
__raw_writel(0, sim->ioaddr + GUARD_CNTL);
sim->errval = 0;
sim->rcv_count = 0;
sim->checking_ts_timing = 1;
sim->state = SIM_STATE_ATR_RECEIVING;
/*Enable the RIM and GPC interrupt, disalbe the CWT interrupt*/
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= SIM_INT_MASK_CWTM;
reg_data &= ~(SIM_INT_MASK_RIM | SIM_INT_MASK_GPCM);
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
}
static int32_t sim_check_rec_data(u32 *reg_data)
{
s32 err = 0;
if (*reg_data & SIM_REC_CWT_ERROR)
err |= SIM_ERROR_CWT;
if (*reg_data & SIM_REC_FRAME_ERROR)
err |= SIM_ERROR_FRAME;
if (*reg_data & SIM_REC_PARITY_ERROR)
err |= SIM_ERROR_PARITY;
return err;
}
static void sim_xmt_fill_fifo(struct sim_t *sim)
{
u32 reg_data;
u32 bytesleft, i;
reg_data = __raw_readl(sim->ioaddr + XMT_FIFO_STAT);
bytesleft = SIM_TX_FIFO_DEPTH - ((reg_data >> 8) & 0x0F);
if (bytesleft > sim->xmt_remaining)
bytesleft = sim->xmt_remaining;
for (i = 0; i < bytesleft; i++) {
__raw_writel(sim->xmt_buffer[sim->xmt_pos],
sim->ioaddr + PORT1_XMT_BUF);
sim->xmt_pos++;
};
sim->xmt_remaining -= bytesleft;
};
static void sim_rcv_read_fifo(struct sim_t *sim)
{
u16 i, count;
u32 reg_data;
count = __raw_readl(sim->ioaddr + RCV_FIFO_CNT);
spin_lock(&sim->lock);
for (i = 0; i < count; i++) {
reg_data = __raw_readl(sim->ioaddr + PORT1_RCV_BUF);
sim->errval |= sim_check_rec_data(&reg_data);
/* T1 mode and t0 mode no parity error, T1 mode SIM module will not produce NACK be
* NACK is disabled. T0 mode to ensure there is no parity error for the current byte
*/
if (!(sim->nack_enable && (reg_data & SIM_REC_PARITY_ERROR))) {
sim->rcv_buffer[sim->rcv_head + sim->rcv_count] = (u8)reg_data;
sim->rcv_count++;
}
if (sim->rcv_head + sim->rcv_count >= SIM_RCV_BUFFER_SIZE) {
pr_err("The software fifo is full,head %d, cnt%d\n", sim->rcv_head, sim->rcv_count);
break;
}
}
spin_unlock(&sim->lock);
}
static void sim_tx_irq_enable(struct sim_t *sim)
{
u32 reg_val;
/*Clear the status and enable the related interrupt*/
reg_val = __raw_readl(sim->ioaddr + XMT_STATUS);
__raw_writel(reg_val, sim->ioaddr + XMT_STATUS);
reg_val = __raw_readl(sim->ioaddr + RCV_STATUS);
__raw_writel(reg_val, sim->ioaddr + RCV_STATUS);
reg_val = __raw_readl(sim->ioaddr + INT_MASK);
/*
*Disable CWT , BWT interrupt when transmitting, it would
*be enabled when rx is enabled just after tx completes
*The timer will be enabled.
*/
reg_val |= SIM_INT_MASK_CWTM | SIM_INT_MASK_BWTM;
reg_val |= SIM_INT_MASK_RIM | SIM_INT_MASK_RTM;
if (sim->xmt_remaining != 0)
reg_val &= ~SIM_INT_MASK_TDTFM;
else{
reg_val &= ~SIM_INT_MASK_TCIM;
/*Enable transmit early complete interrupt.*/
reg_val &= ~SIM_INT_MASK_ETCIM;
}
/*NACK interrupt is enabled only when T0 mode*/
if (sim->protocol_type == SIM_PROTOCOL_T0 || sim->nack_enable != 0)
reg_val &= ~SIM_INT_MASK_XTM;
else
reg_val |= SIM_INT_MASK_XTM;
__raw_writel(reg_val, sim->ioaddr + INT_MASK);
}
static void sim_tx_irq_disable(struct sim_t *sim)
{
u32 reg_val;
/*Disable the NACK interruptand TX related interrupt*/
reg_val = __raw_readl(sim->ioaddr + INT_MASK);
reg_val |= (SIM_INT_MASK_TDTFM | SIM_INT_MASK_TCIM | SIM_INT_MASK_XTM | SIM_INT_MASK_ETCIM);
__raw_writel(reg_val, sim->ioaddr + INT_MASK);
}
static void sim_rx_irq_enable(struct sim_t *sim)
{
u32 reg_data;
/*
* Ensure the CWT timer is enabled.
*/
sim_set_cwt(sim, 1);
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= (SIM_INT_MASK_TCIM | SIM_INT_MASK_TDTFM | SIM_INT_MASK_XTM);
reg_data &= ~(SIM_INT_MASK_RIM | SIM_INT_MASK_CWTM | SIM_INT_MASK_BWTM);
if (sim->protocol_type == SIM_PROTOCOL_T0 || sim->nack_enable != 0)
reg_data &= ~SIM_INT_MASK_RTM;
else
reg_data |= SIM_INT_MASK_RTM;
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
}
static void sim_rx_irq_disable(struct sim_t *sim)
{
u32 reg_val;
reg_val = __raw_readl(sim->ioaddr + INT_MASK);
reg_val |= (SIM_INT_MASK_RIM | SIM_INT_MASK_CWTM | SIM_INT_MASK_BWTM | SIM_INT_MASK_RTM);
__raw_writel(reg_val, sim->ioaddr + INT_MASK);
}
static irqreturn_t sim_irq_handler(int irq, void *dev_id)
{
u32 reg_data, tx_status, rx_status;
struct sim_t *sim = (struct sim_t *) dev_id;
tx_status = __raw_readl(sim->ioaddr + XMT_STATUS);
rx_status = __raw_readl(sim->ioaddr + RCV_STATUS);
__raw_writel(tx_status, sim->ioaddr + XMT_STATUS);
__raw_writel(rx_status, sim->ioaddr + RCV_STATUS);
if (sim->state == SIM_STATE_ATR_RECEIVING &&
sim->checking_ts_timing == 1) {
if ((tx_status & SIM_XMT_STATUS_GPCNT) &&
!(rx_status & SIM_RCV_STATUS_RDRF)) {
/*Disable the GPCNT timer and CWT timer right now*/
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~(SIM_CNTL_GPCNT_CLK_SEL_MASK |
SIM_CNTL_CWTEN);
__raw_writel(reg_data, sim->ioaddr + CNTL);
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= (SIM_INT_MASK_GPCM |
SIM_INT_MASK_CWTM | SIM_INT_MASK_RIM);
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
sim->errval = SIM_ERROR_ATR_DELAY;
complete(&sim->xfer_done);
sim->checking_ts_timing = 0;
} else if (rx_status & SIM_RCV_STATUS_RDRF) {
/*
* Reset/stop the GPCNT timer first.
*/
sim_reset_timer(sim);
/*Enable GPC, CWT interrupt and
*disable the rx full interrupt
*/
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data &= ~(SIM_INT_MASK_GPCM | SIM_INT_MASK_CWTM);
reg_data |= SIM_INT_MASK_RIM;
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
sim_rcv_read_fifo(sim);
/*Clear the GPCNT expiring status*/
__raw_writel(SIM_XMT_STATUS_GPCNT,
sim->ioaddr + XMT_STATUS);
/*ATR each recieved byte will cost 12 ETU, so get the remaining etus*/
reg_data = ATR_MAX_DURATION - sim->rcv_count * 12;
__raw_writel(reg_data, sim->ioaddr + GPCNT);
sim_start_timer(sim, SIM_CNTL_GPCNT_ETU_CLK);
/*Receive fifo threshold set to max value*/
reg_data = SIM_RCV_THRESHOLD_RTH(0) | SIM_RCV_THRESHOLD_RDT(ATR_THRESHOLD_MAX);
__raw_writel(reg_data, sim->ioaddr + RCV_THRESHOLD);
sim->checking_ts_timing = 0;
} else {
pr_err("Unexpected irq when delay checking\n");
}
}
else if (sim->state == SIM_STATE_ATR_RECEIVING) {
if ((rx_status & SIM_RCV_STATUS_CWT) ||
((tx_status & SIM_XMT_STATUS_GPCNT) &&
(sim->rcv_count != 0))) {
/*Disable the GPCNT timer and CWT timer right now*/
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~(SIM_CNTL_GPCNT_CLK_SEL_MASK | SIM_CNTL_CWTEN);
__raw_writel(reg_data, sim->ioaddr + CNTL);
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= (SIM_INT_MASK_GPCM | SIM_INT_MASK_CWTM);
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
if (tx_status & SIM_XMT_STATUS_GPCNT)
sim->errval |= SIM_ERROR_ATR_TIMEROUT;
if (rx_status & SIM_RCV_STATUS_CWT)
sim->errval |= SIM_ERROR_CWT;
sim_rcv_read_fifo(sim);
sim->state = SIM_STATE_ATR_RECEIVED;
complete(&sim->xfer_done);
}
}
else if (sim->state == SIM_STATE_XMTING) {
/*The CWT BWT expire should not happen when in the transmitting state*/
if (tx_status & SIM_XMT_STATUS_ETC) {
/*Once the transmit frame is completed, need to enable CWT timer*/
sim_set_cwt(sim, 1);
}
if (tx_status & SIM_XMT_STATUS_XTE) {
/*Disable TX*/
sim_set_tx(sim, 0);
/*Disalbe the timers*/
sim_set_cwt(sim, 0);
sim_set_bwt(sim, 0);
/*Disable the NACK interruptand TX related interrupt*/
sim_tx_irq_disable(sim);
/*Update the state and status*/
sim->errval |= SIM_ERROR_NACK_THRESHOLD;
sim->state = SIM_STATE_XMT_ERROR;
complete(&sim->xfer_done);
} else if (tx_status & SIM_XMT_STATUS_TDTF && sim->xmt_remaining != 0) {
sim_xmt_fill_fifo(sim);
if (sim->xmt_remaining == 0) {
/*Disable TX threshold interrupt and enable tx complete interrupt*/
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= SIM_INT_MASK_TDTFM;
/*Enable transmit complete and early transmit complete interrupt*/
reg_data &= ~(SIM_INT_MASK_TCIM | SIM_INT_MASK_ETCIM);
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
}
} else if (tx_status & SIM_XMT_STATUS_TC && sim->xmt_remaining == 0) {
/*Disable the NACK interruptand TX related interrupt*/
sim_tx_irq_disable(sim);
sim_set_rx(sim, 1);
/*Update the state and status*/
sim->state = SIM_STATE_XMT_DONE;
complete(&sim->xfer_done);
}
}
/*
* It takes some time to change from SIM_STATE_XMT_DONE to SIM_STATE_RECEIVING
* RX would only be enabled after state becomes SIM_STATE_RECEIVING
*/
else if (sim->state == SIM_STATE_RECEIVING) {
if (rx_status & SIM_RCV_STATUS_RTE) {
/*Disable RX*/
sim_set_rx(sim, 0);
/*Disable the BWT timer and CWT timer right now*/
sim_set_cwt(sim, 0);
sim_set_bwt(sim, 0);
/*Disable the interrupt right now*/
sim_rx_irq_disable(sim);
/*Should we read the fifo or just flush the fifo?*/
sim_rcv_read_fifo(sim);
sim->errval = SIM_ERROR_NACK_THRESHOLD;
sim->state = SIM_STATE_RECEIVE_ERROR;
complete(&sim->xfer_done);
}
if (rx_status & SIM_RCV_STATUS_RDRF) {
sim_rcv_read_fifo(sim);
if (sim->is_fixed_len_rec &&
sim->rcv_count >= sim->expected_rcv_cnt) {
/*Disable the BWT timer and CWT timer right now*/
sim_rx_irq_disable(sim);
/*Add the state judgement to ensure the maybe complete has been impletment in the above "if" case*/
if (sim->state == SIM_STATE_RECEIVING) {
sim->state = SIM_STATE_RECEIVE_DONE;
complete(&sim->xfer_done);
}
}
}
if ((rx_status & SIM_RCV_STATUS_CWT) ||
(rx_status & SIM_RCV_STATUS_BWT) ||
(rx_status & SIM_RCV_STATUS_BGT)) {
/*Disable the BWT timer and CWT timer right now*/
sim_set_cwt(sim, 0);
sim_set_bwt(sim, 0);
sim_rx_irq_disable(sim);
if (rx_status & SIM_RCV_STATUS_BWT) {
sim->errval |= SIM_ERROR_BWT;
}
if (rx_status & SIM_RCV_STATUS_CWT)
sim->errval |= SIM_ERROR_CWT;
if (rx_status & SIM_RCV_STATUS_BGT)
sim->errval |= SIM_ERROR_BGT;
sim_rcv_read_fifo(sim);
/*Add the state judgement to ensure the maybe complete has been impletment in the above "if" case*/
if (sim->state == SIM_STATE_RECEIVING) {
sim->state = SIM_STATE_RECEIVE_DONE;
complete(&sim->xfer_done);
}
}
}
else if ((sim->state == SIM_STATE_RESET_SEQUENCY) &&
(tx_status & SIM_XMT_STATUS_GPCNT))
complete(&sim->xfer_done);
else if (rx_status & SIM_RCV_STATUS_RDRF) {
pr_err("unexpected status %d\n", sim->state);
sim_rcv_read_fifo(sim);
}
return IRQ_HANDLED;
};
static void sim_start(struct sim_t *sim)
{
u32 reg_data, clk_rate, clk_div = 0;
pr_debug("%s entering.\n", __func__);
if (sim->port_index == 1)
__raw_writel(SIM_SETUP_SPS_PORT1, sim->ioaddr + SETUP);
else
__raw_writel(SIM_SETUP_SPS_PORT0, sim->ioaddr + SETUP);
/*1 ~ 5 MHz */
clk_rate = clk_get_rate(sim->clk);
clk_div = (clk_rate + sim->clk_rate - 1) / sim->clk_rate;
__raw_writel(clk_div, sim->ioaddr + CLK_PRESCALER);
/*Set the port pin to be open drained*/
reg_data = __raw_readl(sim->ioaddr + OD_CONFIG);
if (sim->port_index == 1)
reg_data |= SIM_OD_CONFIG_OD_P1;
else
reg_data |= SIM_OD_CONFIG_OD_P0;
__raw_writel(reg_data, sim->ioaddr + OD_CONFIG);
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
/*One pin mode*/
reg_data |= SIM_PORT_CNTL_3VOLT | SIM_PORT_CNTL_STEN;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
/* presense detect */
pr_debug("%s p0_det is 0x%x \n", __func__,
__raw_readl(sim->ioaddr + sim->port_detect_reg));
if (__raw_readl(sim->ioaddr + sim->port_detect_reg)
& SIM_PORT_DETECT_SPDP) {
reg_data = __raw_readl(sim->ioaddr + sim->port_detect_reg);
reg_data &= ~SIM_PORT_DETECT_SPDS;
__raw_writel(reg_data, sim->ioaddr + sim->port_detect_reg);
sim->present = SIM_PRESENT_REMOVED;
sim->state = SIM_STATE_REMOVED;
} else {
reg_data = __raw_readl(sim->ioaddr + sim->port_detect_reg);
reg_data |= SIM_PORT_DETECT_SPDS;
__raw_writel(reg_data, sim->ioaddr + sim->port_detect_reg);
sim->present = SIM_PRESENT_DETECTED;
sim->state = SIM_STATE_DETECTED;
};
/*enable card interrupt. clear interrupt status*/
reg_data = __raw_readl(sim->ioaddr + sim->port_detect_reg);
reg_data |= SIM_PORT_DETECT_SDI;
reg_data |= SIM_PORT_DETECT_SDIM;
__raw_writel(reg_data, sim->ioaddr + sim->port_detect_reg);
};
static void sim_cold_reset_sequency(struct sim_t *sim)
{
u32 reg_data;
sim->state = SIM_STATE_RESET_SEQUENCY;
/*set VCC*/
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
if (sim->sven_low_active)
reg_data &= ~SIM_PORT_CNTL_SVEN;
else
reg_data |= SIM_PORT_CNTL_SVEN;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
msleep(9);
/*enable CLK*/
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data |= SIM_PORT_CNTL_SCEN;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
/*RST low time*/
sim_reset_low_timing(sim, EMV_RESET_LOW_CYCLES);
/*RST high*/
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data |= SIM_PORT_CNTL_SRST;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
/*wait for ATR*/
sim_set_gpc_timer(sim, ATR_MAX_DELAY_CLK);
};
static void sim_deactivate(struct sim_t *sim)
{
u32 reg_data;
pr_debug("%s entering.\n", __func__);
/* Auto powdown to implement the deactivate sequence */
if (sim->present != SIM_PRESENT_REMOVED) {
if (sim->sven_low_active) {
/*Set the RESET to be low*/
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data &= ~SIM_PORT_CNTL_SRST;
writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
usleep_range(2, 5);
/*Set the clock to be low*/
reg_data &= ~SIM_PORT_CNTL_SCEN;
writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
usleep_range(2, 5);
/*Set the sven to be high*/
reg_data |= SIM_PORT_CNTL_SVEN;
writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
} else {
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data |= SIM_PORT_CNTL_SAPD;
__raw_writel(reg_data,
sim->ioaddr + sim->port_ctrl_reg);
reg_data |= SIM_PORT_CNTL_SFPD;
__raw_writel(reg_data,
sim->ioaddr + sim->port_ctrl_reg);
}
} else
pr_err(">>>No card%s\n", __func__);
};
static void sim_cold_reset(struct sim_t *sim)
{
if (sim->present != SIM_PRESENT_REMOVED) {
sim->state = SIM_STATE_DETECTED;
sim->present = SIM_PRESENT_DETECTED;
sim_cold_reset_sequency(sim);
sim_receive_atr_set(sim);
} else {
pr_err("No card%s\n", __func__);
}
};
static void sim_warm_reset_sequency(struct sim_t *sim)
{
u32 reg_data;
sim->state = SIM_STATE_RESET_SEQUENCY;
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data |= (SIM_PORT_CNTL_SRST | SIM_PORT_CNTL_SCEN);
if (sim->sven_low_active)
reg_data &= ~SIM_PORT_CNTL_SVEN;
else
reg_data |= SIM_PORT_CNTL_SVEN;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
usleep_range(20, 25);
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data &= ~SIM_PORT_CNTL_SRST;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
sim_reset_low_timing(sim, EMV_RESET_LOW_CYCLES);
reg_data = __raw_readl(sim->ioaddr + sim->port_ctrl_reg);
reg_data |= SIM_PORT_CNTL_SRST;
__raw_writel(reg_data, sim->ioaddr + sim->port_ctrl_reg);
sim_set_gpc_timer(sim, ATR_MAX_DELAY_CLK);
}
static void sim_warm_reset(struct sim_t *sim)
{
if (sim->present != SIM_PRESENT_REMOVED) {
sim_data_reset(sim);
sim_warm_reset_sequency(sim);
sim_receive_atr_set(sim);
} else {
pr_err("No card%s\n", __func__);
}
};
static int sim_card_lock(struct sim_t *sim)
{
int errval;
/* place holder for true physcial locking */
if (sim->present != SIM_PRESENT_REMOVED)
errval = SIM_OK;
else
errval = -SIM_E_NOCARD;
return errval;
};
static int sim_card_eject(struct sim_t *sim)
{
int errval;
pr_debug("%s entering.\n", __func__);
/* place holder for true physcial locking */
if (sim->present != SIM_PRESENT_REMOVED)
errval = SIM_OK;
else
errval = -SIM_E_NOCARD;
return errval;
};
static int sim_check_baud_rate(sim_baud_t *baud_rate)
{
/*
* The valid value is decribed in the 8.3.3.1 in EMV 4.3
*/
if (baud_rate->fi == 1 && (baud_rate->di == 1 ||
baud_rate->di == 2 || baud_rate->di == 3))
return 0;
return -EINVAL;
}
static int sim_set_baud_rate(struct sim_t *sim)
{
u32 reg_data;
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~(SIM_CNTL_BAUD_SEL_MASK);
switch (sim->baud_rate.di) {
case 1:
reg_data |= SIM_CNTL_BAUD_SEL(0);
break;
case 2:
reg_data |= SIM_CNTL_BAUD_SEL(1);
break;
case 3:
reg_data |= SIM_CNTL_BAUD_SEL(2);
break;
default:
pr_err("Invalid baud Di, Using default 372 / 1\n");
reg_data |= SIM_CNTL_BAUD_SEL(0);
break;
}
__raw_writel(reg_data, sim->ioaddr + CNTL);
return 0;
}
static int sim_check_timing_data(sim_timing_t *timing_data)
{
if (timing_data->wwt > 0xFFFF ||
timing_data->cwt > 0xFFFF ||
timing_data->bgt > 0xFFFF ||
timing_data->cgt > 0xFF) {
/*Check whether the counter is out of the scope of SIM IP*/
pr_err("The timing value is out of scope of IP\n");
return -EINVAL;
}
return 0;
}
static void sim_set_timer_counter(struct sim_t *sim)
{
if (sim->timing_data.wwt != 0 &&
sim->protocol_type == SIM_PROTOCOL_T0) {
sim->timing_data.cwt = sim->timing_data.wwt;
sim->timing_data.bwt = sim->timing_data.wwt;
}
if (sim->timing_data.bgt != 0) {
__raw_writel(sim->timing_data.bgt, sim->ioaddr + BGT);
}
if (sim->timing_data.cwt != 0)
__raw_writel(sim->timing_data.cwt, sim->ioaddr + CHAR_WAIT);
if (sim->timing_data.bwt != 0) {
__raw_writel(sim->timing_data.bwt & 0x0000FFFF, sim->ioaddr + BWT);
__raw_writel((sim->timing_data.bwt >> 16) & 0x0000FFFF,
sim->ioaddr + BWT_H);
}
if (sim->timing_data.cgt == 0xFF && sim->protocol_type == SIM_PROTOCOL_T0)
/* From EMV4.3 , CGT =0xFF in T0 mode means 12 ETU.
* Set register to be 12 ETU for transmitting and receiving.
*/
__raw_writel(0 , sim->ioaddr + GUARD_CNTL);
else if (sim->timing_data.cgt == 0xFF && sim->protocol_type == SIM_PROTOCOL_T1)
/* From EMV4.3 , CGT =0xFF in T1 mode means 11 ETU.
* Set register to be 12 ETU for transmitting and receiving.
*/
__raw_writel(0x1FF , sim->ioaddr + GUARD_CNTL);
/*For the T1 mode, use 11ETU to receive.*/
else if (sim->protocol_type == SIM_PROTOCOL_T1)
__raw_writel((sim->timing_data.cgt | SIM_GUARD_CNTL_RCVR11), sim->ioaddr + GUARD_CNTL);
else
/*sim->protocol_type == SIM_PROTOCOL_T0*/
__raw_writel(sim->timing_data.cgt, sim->ioaddr + GUARD_CNTL);
}
static void sim_xmt_start(struct sim_t *sim)
{
u32 reg_val;
/*Set TX threshold if there are remaing data*/
if (sim->xmt_remaining != 0) {
reg_val = __raw_readl(sim->ioaddr + XMT_THRESHOLD);
reg_val &= ~SIM_XMT_THRESHOLD_TDT_MASK;
reg_val |= SIM_XMT_THRESHOLD_TDT(TX_FIFO_THRESHOLD);
__raw_writel(reg_val, sim->ioaddr + XMT_THRESHOLD);
}
sim_tx_irq_enable(sim);
/*Enable BWT and disalbe CWT timers when tx*/
sim_set_bwt(sim, 1);
sim_set_cwt(sim, 0);
/*Disalbe RX*/
sim_set_rx(sim, 0);
/*Enable TX*/
sim_set_tx(sim, 1);
}
static void sim_flush_fifo(struct sim_t *sim, u8 flush_tx, u8 flush_rx)
{
u32 reg_val;
reg_val = __raw_readl(sim->ioaddr + RESET_CNTL);
if (flush_tx)
reg_val |= SIM_RESET_CNTL_FLUSH_XMT;
if (flush_rx)
reg_val |= SIM_RESET_CNTL_FLUSH_RCV;
__raw_writel(reg_val, sim->ioaddr + RESET_CNTL);
usleep_range(2, 3);
if (flush_tx)
reg_val &= ~(SIM_RESET_CNTL_FLUSH_XMT);
if (flush_rx)
reg_val &= ~(SIM_RESET_CNTL_FLUSH_RCV);
__raw_writel(reg_val, sim->ioaddr + RESET_CNTL);
}
static void sim_change_rcv_threshold(struct sim_t *sim)
{
u32 rx_threshold = 0;
u32 reg_val = 0;
if (sim->is_fixed_len_rec) {
rx_threshold = sim->expected_rcv_cnt - sim->rcv_count;
reg_val = __raw_readl(sim->ioaddr + RCV_THRESHOLD);
reg_val &= ~(SIM_RCV_THRESHOLD_RDT_MASK);
reg_val |= SIM_RCV_THRESHOLD_RDT(rx_threshold);
__raw_writel(reg_val, sim->ioaddr + RCV_THRESHOLD);
}
}
static void sim_start_rcv(struct sim_t *sim)
{
sim_set_baud_rate(sim);
if (sim->protocol_type == SIM_PROTOCOL_T0)
sim_set_nack(sim, 1);
else if (sim->protocol_type == SIM_PROTOCOL_T1)
sim_set_nack(sim, 0);
/*Set RX threshold*/
if (sim->protocol_type == SIM_PROTOCOL_T0)
__raw_writel(SIM_RCV_THRESHOLD_RTH(sim->nack_threshold) |
SIM_RCV_THRESHOLD_RDT(RX_FIFO_THRESHOLD), sim->ioaddr + RCV_THRESHOLD);
else
__raw_writel(SIM_RCV_THRESHOLD_RDT(RX_FIFO_THRESHOLD), sim->ioaddr + RCV_THRESHOLD);
/*Clear status and enable interrupt*/
sim_rx_irq_enable(sim);
/*Disalbe TX and Enable Rx*/
sim_set_rx(sim, 1);
sim_set_tx(sim, 0);
}
static void sim_polling_delay(struct sim_t *sim, u32 delay)
{
u32 reg_data;
/*Reset the timer*/
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~SIM_CNTL_GPCNT_CLK_SEL_MASK;
reg_data |= SIM_CNTL_GPCNT_CLK_SEL(0);
__raw_writel(reg_data, sim->ioaddr + CNTL);
/*Clear the interrupt status*/
__raw_writel(SIM_XMT_STATUS_GPCNT, sim->ioaddr + XMT_STATUS);
/*Disable timer interrupt*/
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= SIM_INT_MASK_GPCM;
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
__raw_writel(delay, sim->ioaddr + GPCNT);
/*Set the ETU as clock source and start timer*/
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~SIM_CNTL_GPCNT_CLK_SEL_MASK;
reg_data |= SIM_CNTL_GPCNT_CLK_SEL(3);
__raw_writel(reg_data, sim->ioaddr + CNTL);
/*Loop for timeout*/
while (!(__raw_readl(sim->ioaddr + XMT_STATUS) & SIM_XMT_STATUS_GPCNT))
usleep_range(10, 20);
__raw_writel(SIM_XMT_STATUS_GPCNT, sim->ioaddr + XMT_STATUS);
}
void sim_clear_rx_buf(struct sim_t *sim)
{
unsigned int i;
for (i = 0; i < SIM_RCV_BUFFER_SIZE; i++)
sim->rcv_buffer[i] = 0;
sim->rcv_count = 0;
sim->rcv_head = 0;
}
static long sim_ioctl(struct file *file,
unsigned int cmd, unsigned long arg)
{
int ret, errval = SIM_OK;
unsigned long timeout;
u32 reg_data;
u32 delay;
u32 copy_cnt, val;
unsigned long flags;
unsigned char __user *atr_buffer;
unsigned char __user *xmt_buffer;
unsigned char __user *rcv_buffer;
struct sim_t *sim = (struct sim_t *) file->private_data;
pr_debug("%s entering.\n", __func__);
switch (cmd) {
case SIM_IOCTL_GET_ATR:
if (sim->present != SIM_PRESENT_DETECTED) {
pr_err("NO card ...\n");
errval = -SIM_E_NOCARD;
break;
};
sim->timeout = ATR_TIMEOUT * HZ;
val = 0;
ret = copy_to_user(&(((sim_atr_t *)arg)->size), &val,
sizeof((((sim_atr_t *)arg)->size)));
timeout = wait_for_completion_interruptible_timeout(&sim->xfer_done,
sim->timeout);
/*Disalbe the GPCNT timer and CWT timer right now*/
reg_data = __raw_readl(sim->ioaddr + CNTL);
reg_data &= ~(SIM_CNTL_GPCNT_CLK_SEL_MASK | SIM_CNTL_CWTEN);
__raw_writel(reg_data, sim->ioaddr + CNTL);
reg_data = __raw_readl(sim->ioaddr + INT_MASK);
reg_data |= (SIM_INT_MASK_GPCM | SIM_INT_MASK_CWTM);
__raw_writel(reg_data, sim->ioaddr + INT_MASK);
if (timeout == 0) {
pr_err("ATR timeout\n");
errval = -SIM_E_TIMEOUT;
break;
}
ret = copy_to_user(&(((sim_atr_t *)arg)->size), &sim->rcv_count,
sizeof(sim->rcv_count));
if (ret) {
pr_err("ATR ACCESS rcv_count Error, %d\n", ret);
errval = -SIM_E_ACCESS;
break;
}
__get_user(atr_buffer, &((sim_atr_t __user *)arg)->atr_buffer);
ret = copy_to_user(atr_buffer, sim->rcv_buffer, sim->rcv_count);
if (ret) {
pr_err("ATR ACCESS buffer Error %d %d\n", sim->rcv_count, ret);
errval = -SIM_E_ACCESS;
break;
}
ret = copy_to_user(&(((sim_atr_t *)arg)->errval), &sim->errval,
sizeof(sim->errval));
if (ret) {
pr_err("ATR ACCESS Error\n");
errval = -SIM_E_ACCESS;
break;
}
sim->rcv_count = 0;
sim->rcv_head = 0;
sim->errval = 0;
break;
case SIM_IOCTL_DEACTIVATE:
sim_deactivate(sim);
break;
case SIM_IOCTL_COLD_RESET:
sim->present = SIM_PRESENT_REMOVED;
sim->state = SIM_STATE_REMOVED;
sim_reset_module(sim);
sim_data_reset(sim);
sim_start(sim);
sim_cold_reset(sim);
break;
case SIM_IOCTL_WARM_RESET:
sim_warm_reset(sim);
break;
case SIM_IOCTL_XMT:
ret = copy_from_user(&sim->xmt_remaining, &(((sim_xmt_t *)arg)->xmt_length),
sizeof(uint32_t));
if (ret || sim->xmt_remaining > SIM_XMT_BUFFER_SIZE) {
pr_err("copy error or to big buffer\n");
errval = -EINVAL;
break;
}
__get_user(xmt_buffer, &((sim_xmt_t *)arg)->xmt_buffer);
ret = copy_from_user(sim->xmt_buffer, xmt_buffer, sim->xmt_remaining);
if (ret) {
pr_err("Copy Error\n");
errval = ret;
break;
}
sim_clear_rx_buf(sim);
sim_set_cwt(sim, 0);
sim_set_bwt(sim, 0);
/*Flush the tx rx fifo*/
sim_flush_fifo(sim, 1, 1);
sim->xmt_pos = 0;
sim->errval = 0;
sim_xmt_fill_fifo(sim);
sim_set_baud_rate(sim);
if (sim->protocol_type == SIM_PROTOCOL_T0)
sim_set_nack(sim, 1);
else if (sim->protocol_type == SIM_PROTOCOL_T1)
sim_set_nack(sim, 0);
else {
pr_err("Invalid protocol not T0 or T1\n");
errval = -EINVAL;
break;
}
sim_set_timer_counter(sim);
sim_xmt_start(sim);
sim->state = SIM_STATE_XMTING;
sim->timeout = TX_TIMEOUT * HZ;
timeout = wait_for_completion_interruptible_timeout(&sim->xfer_done,
sim->timeout);
if (timeout == 0) {
/*Disable the NACK interruptand TX related interrupt*/
sim_tx_irq_disable(sim);
pr_err("tx timeout\n");
}
if (timeout == 0 || sim->state == SIM_STATE_XMT_ERROR) {
pr_err("TX error\n");
/*Disable timers*/
sim_set_cwt(sim, 0);
sim_set_bwt(sim, 0);
/*Disable TX*/
sim_set_tx(sim, 0);
/*Flush the tx fifos*/
sim_flush_fifo(sim, 1, 0);
if (timeout == 0)
errval = -SIM_E_TIMEOUT;
else
errval = -SIM_E_NACK;
ret = copy_to_user(&(((sim_atr_t *)arg)->errval), &sim->errval,
sizeof(sim->errval));
sim->errval = 0;
break;
}
/*Copy the error status to user space*/
ret = copy_to_user(&(((sim_atr_t *)arg)->errval), &sim->errval,
sizeof(sim->errval));
sim->last_is_tx = true;
/*Start RX*/
sim->errval = 0;
sim->state = SIM_STATE_RECEIVING;
sim_start_rcv(sim);
break;
case SIM_IOCTL_RCV:
if (sim->present != SIM_PRESENT_DETECTED) {
errval = -SIM_E_NOCARD;
break;
}
sim->is_fixed_len_rec = 0;
val = 0;
ret = copy_from_user(&sim->expected_rcv_cnt, &(((sim_rcv_t *)arg)->rcv_length),
sizeof(sim->expected_rcv_cnt));
/*Set the length to be 0 at first*/
ret = copy_to_user(&(((sim_rcv_t *)arg)->rcv_length), &val,
sizeof(val));
/*Set error value to be 0 at first*/
ret = copy_to_user(&(((sim_rcv_t *)arg)->errval), &val,
sizeof(val));
if (sim->expected_rcv_cnt != 0)
sim->is_fixed_len_rec = 1;
if (sim->is_fixed_len_rec && sim->rcv_count >= sim->expected_rcv_cnt)
goto copy_data;
if (sim->state != SIM_STATE_RECEIVING) {
sim_set_timer_counter(sim);
/*Enable CWT BWT*/
sim_set_cwt(sim, 1);
sim_set_bwt(sim, 1);
sim->state = SIM_STATE_RECEIVING;
sim_start_rcv(sim);
}
spin_lock_irqsave(&sim->lock, flags);
if (sim->is_fixed_len_rec && sim->rcv_count < sim->expected_rcv_cnt)
sim_change_rcv_threshold(sim);
spin_unlock_irqrestore(&sim->lock, flags);
sim->timeout = RX_TIMEOUT * HZ;
timeout = wait_for_completion_interruptible_timeout(&sim->xfer_done,
sim->timeout);
if (timeout == 0) {
pr_err("Receiving timeout\n");
sim_set_cwt(sim, 0);
sim_set_bwt(sim, 0);
sim_rx_irq_disable(sim);
errval = -SIM_E_TIMEOUT;
break;
}
copy_data:
if (sim->is_fixed_len_rec)
copy_cnt = sim->rcv_count >= sim->expected_rcv_cnt ? sim->expected_rcv_cnt : sim->rcv_count;
else
copy_cnt = sim->rcv_count;
ret = copy_to_user(&(((sim_rcv_t *)arg)->rcv_length), &copy_cnt,
sizeof(copy_cnt));
if (ret) {
pr_err("ATR ACCESS Error\n");
errval = -SIM_E_ACCESS;
break;
}
__get_user(rcv_buffer, &((sim_rcv_t *)arg)->rcv_buffer);
ret = copy_to_user(rcv_buffer, &sim->rcv_buffer[sim->rcv_head], copy_cnt);
if (ret) {
pr_err("ATR ACCESS Error\n");
errval = -SIM_E_ACCESS;
break;
}
ret = copy_to_user(&(((sim_rcv_t *)arg)->errval), &sim->errval,
sizeof(sim->errval));
if (ret) {
pr_err("ATR ACCESS Error\n");
errval = -SIM_E_ACCESS;
break;
}
/*Reset the receiving count and errval*/
spin_lock_irqsave(&sim->lock, flags);
sim->rcv_head += copy_cnt;
sim->rcv_count -= copy_cnt;
sim->errval = 0;
spin_unlock_irqrestore(&sim->lock, flags);
sim->last_is_tx = false;
break;
case SIM_IOCTL_SET_PROTOCOL:
ret = copy_from_user(&sim->protocol_type, (int *)arg,
sizeof(int));
if (ret)
errval = -SIM_E_ACCESS;
break;
case SIM_IOCTL_SET_TIMING:
ret = copy_from_user(&sim->timing_data, (sim_timing_t *)arg,
sizeof(sim_timing_t));
if (ret) {
pr_err("Copy Error\n");
errval = ret;
break;
}
ret = sim_check_timing_data(&sim->timing_data);
if (ret)
errval = ret;
break;
case SIM_IOCTL_SET_BAUD:
ret = copy_from_user(&sim->baud_rate, (sim_baud_t *)arg,
sizeof(sim_baud_t));
if (ret) {
pr_err("Copy Error\n");
errval = ret;
break;
}
sim_check_baud_rate(&sim->baud_rate);
break;
case SIM_IOCTL_WAIT:
ret = copy_from_user(&delay, (unsigned int *)arg,
sizeof(unsigned int));
if (ret) {
pr_err("\nWait Copy Error\n");
errval = ret;
break;
}
sim_polling_delay(sim, delay);
break;
case SIM_IOCTL_GET_PRESENSE:
if (put_user(sim->present, (int *)arg))
errval = -SIM_E_ACCESS;
break;
case SIM_IOCTL_CARD_LOCK:
errval = sim_card_lock(sim);
break;
case SIM_IOCTL_CARD_EJECT:
errval = sim_card_eject(sim);
break;
};
return errval;
};
static int sim_open(struct inode *inode, struct file *file)
{
int errval = SIM_OK;
struct sim_t *sim = dev_get_drvdata(sim_dev.parent);
file->private_data = sim;
spin_lock_init(&sim->lock);
pr_debug("%s entering.\n", __func__);
if (!sim->ioaddr) {
errval = -ENOMEM;
return errval;
}
if (!sim->open_cnt)
clk_prepare_enable(sim->clk);
sim->open_cnt = 1;
errval = sim_reset_module(sim);
sim_data_reset(sim);
return errval;
};
static int sim_release(struct inode *inode, struct file *file)
{
u32 reg_data;
struct sim_t *sim = (struct sim_t *) file->private_data;
/* disable presense detection */
reg_data = __raw_readl(sim->ioaddr + sim->port_detect_reg);
__raw_writel(reg_data | SIM_PORT_DETECT_SDIM,
sim->ioaddr + sim->port_detect_reg);
if (sim->present != SIM_PRESENT_REMOVED)
sim_deactivate(sim);
if (sim->open_cnt)
clk_disable_unprepare(sim->clk);
sim->open_cnt = 0;
return 0;
};
static const struct file_operations sim_fops = {
.owner = THIS_MODULE,
.open = sim_open,
.release = sim_release,
.unlocked_ioctl = sim_ioctl,
};
static struct miscdevice sim_dev = {
MISC_DYNAMIC_MINOR,
"mxc_sim",
&sim_fops
};
static struct platform_device_id imx_sim_devtype[] = {
{
.name = "imx7d-sim",
.driver_data = 0,
}, {
.name = "imx6ul-sim",
.driver_data = SIM_QUIRK_TKT259347,
}, {
/* sentinel */
}
};
enum imx_sim_type {
IMX7D_SIM = 0,
IMX6UL_SIM,
};
static const struct of_device_id sim_imx_dt_ids[] = {
{ .compatible = "fsl,imx7d-sim",
.data = &imx_sim_devtype[IMX7D_SIM], },
{ .compatible = "fsl,imx6ul-sim",
.data = &imx_sim_devtype[IMX6UL_SIM], },
{ /* sentinel */ }
};
MODULE_DEVICE_TABLE(of, sim_imx_dt_ids);
static int sim_probe(struct platform_device *pdev)
{
int ret = 0;
const struct of_device_id *of_id;
struct sim_t *sim = NULL;
struct device_node *of_node = pdev->dev.of_node;
sim = devm_kzalloc(&pdev->dev, sizeof(struct sim_t),
GFP_KERNEL);
if (!sim) {
dev_err(&pdev->dev, "can't allocate enough memory\n");
return -ENOMEM;
}
of_id = of_match_device(sim_imx_dt_ids, &pdev->dev);
if (of_id)
pdev->id_entry = of_id->data;
else
return -EINVAL;
sim->clk_rate = FCLK_FREQ;
sim->open_cnt = 0;
sim->res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!sim->res) {
pr_err("Can't get the MEMORY\n");
return -ENOMEM;
}
sim->ioaddr = devm_ioremap_resource(&pdev->dev, sim->res);
dev_dbg(&pdev->dev, "mapped base address: 0x%08x\n", (u32)sim->ioaddr);
if (IS_ERR(sim->ioaddr)) {
dev_err(&pdev->dev,
"failed to get ioremap base\n");
ret = PTR_ERR(sim->ioaddr);
return ret;
}
/* request the sim clk and sim_serial_clk */
sim->clk = devm_clk_get(&pdev->dev, "sim");
if (IS_ERR(sim->clk)) {
ret = PTR_ERR(sim->clk);
pr_err("Get CLK ERROR !\n");
return ret;
}
pr_debug("sim clock:%lu\n", clk_get_rate(sim->clk));
sim->ipb_irq = platform_get_irq(pdev, 0);
if (sim->ipb_irq < 0) {
dev_err(&pdev->dev, "No ipb irq line provided\n");
return -ENOENT;
}
if (devm_request_irq(&pdev->dev, sim->ipb_irq, sim_irq_handler,
0, "mxc_sim_ipb", sim)) {
dev_err(&pdev->dev, "can't claim irq %d\n", sim->ipb_irq);
return -ENOENT;
}
sim->sven_low_active = of_property_read_bool(of_node,
"sven_low_active");
ret = of_property_read_u32(of_node, "port", &sim->port_index);
if (ret)
sim->port_index = 0;
sim->port_ctrl_reg = (sim->port_index == 0) ?
PORT0_CNTL : PORT1_CNTL;
sim->port_detect_reg = (sim->port_index == 0) ?
PORT0_DETECT : PORT1_DETECT;
sim->quirks = pdev->id_entry->driver_data;
platform_set_drvdata(pdev, sim);
/*
*@todo: Need to figure a better way if possible.
*/
sim_dev.parent = &(pdev->dev);
misc_register(&sim_dev);
return 0;
}
static int sim_remove(struct platform_device *pdev)
{
struct sim_t *sim = platform_get_drvdata(pdev);
if (sim->open_cnt)
clk_disable_unprepare(sim->clk);
misc_deregister(&sim_dev);
return 0;
}
#ifdef CONFIG_PM
static int sim_suspend(struct platform_device *pdev, pm_message_t state)
{
struct sim_t *sim = platform_get_drvdata(pdev);
if (sim->open_cnt)
clk_disable_unprepare(sim->clk);
pinctrl_pm_select_sleep_state(&pdev->dev);
return 0;
}
static int sim_resume(struct platform_device *pdev)
{
struct sim_t *sim = platform_get_drvdata(pdev);
if (sim->open_cnt)
clk_prepare_enable(sim->clk);
pinctrl_pm_select_default_state(&pdev->dev);
return 0;
}
#else
#define sim_suspend NULL
#define sim_resume NULL
#endif
static struct platform_driver sim_driver = {
.driver = {
.name = DRIVER_NAME,
.owner = THIS_MODULE,
.of_match_table = sim_imx_dt_ids,
},
.probe = sim_probe,
.remove = sim_remove,
.suspend = sim_suspend,
.resume = sim_resume,
.id_table = imx_sim_devtype,
};
static int __init sim_drv_init(void)
{
return platform_driver_register(&sim_driver);
}
static void __exit sim_drv_exit(void)
{
platform_driver_unregister(&sim_driver);
}
module_init(sim_drv_init);
module_exit(sim_drv_exit);
MODULE_AUTHOR("Freescale Semiconductor, Inc.");
MODULE_DESCRIPTION("MXC SIM Driver");
MODULE_LICENSE("GPL");